DE60224212T2 - NETWORK WITH MULTIPLE SUB NETWORKS - Google Patents

Abstract

The invention relates to a network with several subnetworks, which are organized either decentrally or centrally and can be connected in each case each by bridge terminals, a proxy terminal for a bridge terminal being set up in at least one of the subnetworks, which proxy terminal during an absence (dictated by frequency, time, code, or other factors) of the bridge terminal accepts all data directed to the bridge terminal or to be forwarded thereby, temporarily stores the data, and forwards said data to the bridge terminal when this is present again.

Description

The Invention relates to a network with several sub-networks, each over Bridge terminal can be connected.

The Sub-networks can on different frequencies or codes or too different Times work. Communicate within each individual network terminals wirelessly over one or several radio links. Furthermore, within a Sub-network a central control station exist or not.

One such subnetwork is, for example, Habetha, J .; Nadler, M .: "Concept of a Centralized Multihop Ad Hoc Network ", Proceedings European Wireless, Dresden, Sept. 2000, known. In this known network, neighboring ones operate Subnetworks on different frequencies and are interconnected by bridge terminals connected in the overlapping area of two Sub-networks are located. The bridge terminals take turns on the operation within the two sub-networks part by switching from one frequency to another. There is the possibility, any transmission to the bridge terminal to stop while it operates on the frequency of another sub-network. this will accomplished by a central control station in each of the sub-networks, the for the allocation of transmission resources within the sub-network is and about informed about the absence of the bridge terminal is. The central control station therefore forgives during the Absence of the bridge terminal no transmission capacity to others Stations one to the bridge terminal directed transmission have registered.

Of the Article "User-dependent Perfect-scheduling Multiple Access (UPMA) For Wireless Ad Hoc Internet Access, "Li Jiangdon et al., Proceedings of 16th International Conference on Communication Technology (ICCT00), Vol. 2, 21 August 2000 (2000-08-21) -25. August 2000 (2000-08-25), p. 1714-1717, XP010526693 Beijing, China, discloses a centralized ad hoc network in which a Cluster controller stores packets that are sent to a gateway node be directed, with the packets immediately after the gateway node sent back packets to this cluster to the gateway node be sent.

Of the The invention is based on the object, a network with improved communications between the sub-networks. This task is done by the characteristics of the independent claims solved. In particular, it is according to the invention with a network according to claim 4 solved, with multiple sub-networks, each connected via bridge terminals, which provides that in at least one of the networks a representative terminal for a bridge terminal is set up during that the absence of the bridge terminal to the bridge terminal directed or from the bridge terminal receives data to be forwarded, which caches data and forwards said data to the bridge terminal, if this is available again.

Therefore chooses according to the invention a bridge terminal another station as his representative during the Absence of the bridge terminal all to the bridge terminal receives and caches directed data. If that Bridge terminal back to the frequency (the code or the time range) of the considered sub-network returns, transmits the representative of the bridge terminal all in the meantime for it received data.

The The present invention advantageously relates to a network, either no central control station in at least one subnetwork exists or for any other reason a transmission to the bridge terminal during that Absence can not be prevented.

The Task is also according to the invention with a Bridge terminal according to claim 1 and a representative terminal according to claim 8.

The Networks can be either decentralized or centrally organized.

The Absence may be due to frequency, time, code or other reasons be.

If in a sub-network a central control station exists, however a transmission to the bridge terminal while whose absence is not possible is, according to one preferred embodiment invention, the central control station from the bridge terminal selected as his representative.

embodiments The invention will be explained in more detail below with reference to FIGS. Show it:

1 an ad hoc network with three sub-networks, each containing terminals intended for radio transmission,

2 a terminal of the local network 1 .

3 a radio device of the terminal 2 and

4 an embodiment of a provided for connecting two sub-networks bridge terminals and the representative terminal of this bridge terminals.

The in the following illustrated embodiment refers to ad-hoc networks, self-organizing unlike traditional networks are. Each terminal in such an ad hoc network can have one Enable access to a fixed network and can be used immediately. One Ad hoc network is characterized in that the structure and the number of participants within preset limits is not is fixed. For example, a communication device be taken from a participant from the network or involved. Unlike traditional mobile networks is an ad hoc network not dependent on a fixed infrastructure.

The Size of the area of the Ad hoc network is usually much larger than the transmission range a terminal. A communication between two terminals can Therefore, the activation of additional terminals required, so communicating these messages or data between the two Transmit terminals can. Such ad hoc networks involve message forwarding and data about A terminal is necessary as multihop ad hoc networks designated. Multihop ad hoc networks can either be on a frequency (or a code or a time range) are operated, or consist of sub-networks operating at different frequencies, Codes or time ranges work. A subnetwork of the ad hoc network can be done through, for example Wireless terminals connected terminals formed around a table participants become. Such terminals can z. B. Communication devices for wireless exchange of documents, Be pictures, etc.

It you can specify two types of ad hoc networks. These are decentralized and centralized ad hoc networks. In a decentralized Ad-hoc network the communication between the terminals is decentralized, d. H. each terminal can communicate directly with any other terminal, provided that the terminals are each in the transmission area the other terminal. The advantage of a decentralized ad hoc network is its simplicity and robustness against mistakes. For a centralized ad hoc network certain functions, such. B. the function of multiple access a terminal to the radio transmission medium (Medium Access Control = MAC) from a specific terminal per Sub-network controlled. This terminal is called a central terminal or central controller (Central Controller = CC). These functions must not always run from the same terminal, but can from one operating as a central controller terminal to another then be handed over as a central controller operating terminal. The advantage of a central ad hoc network is that in this in a simple way an agreement on the quality of service (Quality of Service = QoS) possible is. An example for a centralized ad-hoc network is a network that subscribes to the HIPERLAN / 2 Home Environment Extension (HEE) is organized (See J. Habetha, A. Hettich, J. Peetz, Y. Du, "Central Controller Handover Procedure for ETSI-BRAN HIPERLAN / 2 Ad Hoc Networks and Clustering with Quality of Service Gurantees ", 1st IEEE Annual Workshop on Mobile Ad Hoc Networking & Computing, 11. Aug. 2000).

In 1 is an embodiment of an ad hoc network with three sub-networks 1 to 3 shown, each with multiple terminals 4 to 16 contain. Components of the subnetwork 1 are the terminals 4 to 9 , the subnetwork 2 the terminals 4 and 10 to 12 and the subnetwork 3 the terminals 5 and 13 to 16 , In a sub-network, each belonging to a sub-network terminals exchange data over radio links. In the 1 drawn ellipses indicate the radio range of a subnetwork ( 1 to 3 ), in which a largely problem-free radio transmission is possible between the terminals belonging to the subnetwork.

The terminals 4 and 5 These are called bridge terminals because they exchange data between two sub-networks 1 and 2 respectively. 1 and 3 enable. The bridge terminal 4 is for the traffic between the subnets 1 and 2 and the bridge terminal 5 for the traffic between the sub-networks 1 and 3 responsible.

A terminal 4 to 16 of the local network 1 may be a mobile or fixed communication device and includes, for example, at least one station 17 , a connection control device 18 and a radio device 19 with antenna 20 , like this 2 shows. A station 17 may for example be a portable computer, telephone, etc.

As 3 shows contains a radio device 19 the terminals 6 to 16 except the antenna 20 a high frequency circuit 21 , a modem 22 and a protocol device 23 , The protocol device 23 forms from that of the connection control device 18 received data stream packet units. A package unit contains parts of the data current and additional from the protocol device 23 formed tax information. The protocol device uses protocols for the LLC layer (LLC = Logical Link Control) and the MAC layer (MAC = Medium Access Control). The MAC layer controls the multiple access of a terminal to the radio transmission medium, and the LLC layer performs flow and error control.

As mentioned above, in a subnet 1 to 3 a centralized ad hoc network, a specific terminal will be responsible for the control and management functions, and will be referred to as the central controller in this case. The controller also works as a normal terminal in the associated subnetwork. The controller is z. B. for the registration of terminals that take up operation in the sub-network, for establishing a connection between at least two terminals in the radio transmission medium, responsible for resource management and access control in the radio transmission medium. For example, a terminal of a sub-network after registration and after the registration of a transfer request from the controller assigned transmission capacity for data (packet units).

In the ad hoc network, the data may be transferred between the terminals according to a TDMA, FDMA, CDMA or CSMA (Time Division Multiplex Access, FMA = Frequency Division Multiplex Access, CDMA = Code Division Multiplex Access, CSMA = Carrier Sense Multiple Access). The procedures can also be combined. Every subnetwork 1 to 3 of the local network are associated with a number of particular channels, referred to as channel bundles. A channel is characterized by a frequency range, a time range or z. B. in the CDMA method determined by a spreading code. For example, any subnetwork can 1 to 3 for data exchange a specific, each different frequency range with a carrier frequency f _i are available. In such a frequency range, for example, data can be transmitted by means of the TDMA or CSMA method. This can be the sub-network 1 the carrier frequency f ₁ , the sub-network 2 the carrier frequency f ₂ and the sub-network 3 be assigned to the carrier frequency f ₃ . The bridge terminal 4 works on the one hand with the carrier frequency f ₁ to connect to the other terminals of the sub-network 1 to carry out a data exchange, and on the other hand with the carrier frequency f ₂ , to the other terminals of the sub-network 2 to carry out a data exchange. The second bridge terminal included in the local network 5 which data is between the sub-networks 1 and 3 transmits, works with the carrier frequencies f ₁ and f ₃ .

In 4 a block diagram of an embodiment of a bridge terminal is shown. The design of the representative terminal can also be carried out in the same way. The radio switching device of this bridge terminal each contains a protocol device 24 , a modem 25 and a high-frequency circuit 26 with antenna 27 , With the protocol device 24 is a radio switching device 28 In addition, connected to a connection control device 29 and a cache device 30 connected. The cache device 30 In this embodiment, it contains a memory element and is used for buffering data and is realized as a FIFO building block (First In First Out), ie the data is output from the buffering device in the order 30 read in which they have been registered. Of particular importance is the existence of a caching facility for the agent terminal, as it caches all data directed to the bridge terminal during its absence. The memory may be divided into logical areas for separately storing the data of different connections. This in 4 shown terminal can also work as a normal terminal. To the connection control device 29 connected stations that are not in 4 are then supplied via the connection control device 29 Data for the radio switching device 28 ,

The bridge terminal after 4 is alternately synchronized with a first and second subnetwork. Synchronization is understood to mean the entire process of the integration of a terminal in the sub-network until the exchange of data. When the bridge terminal is synchronized with the first subnetwork, it can exchange data with its neighbor radio terminals and with a possibly existing controller of that first subnetwork. Are from the connection control device 29 Data to the radio switching device 28 provided that its destination is a terminal or the controller of the first sub-network or a terminal or controller of another sub-network to be reached via the first sub-network, then the radio switching device passes this data directly to the protocol device 24 further. In the protocol device 24 the data is buffered until the time specified by the controller for transmission has been reached. If that of the connection control device 29 outputted data to a terminal or the controller of the second sub-network or to another to be reached via the second sub-network sub-network, the radio transmission must be delayed until the period in which the bridge terminal with the second sub-network is synchronized. Therefore, the directs Radio switching device, the data whose destination is in the second sub-network or whose destination is to be reached via the second sub-network, to the temporary storage device 30 which caches the data until the bridge terminal is synchronized with the second subnetwork.

When data is received from one terminal or the controller of the first sub-network from the bridge terminal and its destination is a terminal or the controller of the second sub-network or a terminal or controller of another sub-network to be reached via the second sub-network Also, these data will also be in synchronization with the second subnetwork in the cache device 30 stored. Data whose destination is a station of the bridge terminal is transmitted directly via the radio switching device 28 to the connection control device 29 which then routes the received data to the desired station. Data whose destination is neither a station of the bridge terminal nor a terminal or controller of the second sub-network, for example, is sent to another bridge terminal.

After the synchronization change of the bridge terminal from the first to the second sub-network, those in the buffer device 30 data in the write order again from the cache device 30 read. Subsequently, during the period of synchronization of the bridge terminal with the second sub-network, all data whose destination is a terminal or the controller of the second sub-network or another sub-network to be reached via the second sub-network can be immediately deleted from the radio switching device 28 to the protocol device 24 passed on and only the data whose destination is a terminal or the controller of the first sub-network or another to be reached via the first sub-network sub-network in the cache device 30 get saved.

The Representative terminal is similar like the bridge terminal executed leads however no frequency changes. It is by a one-time or periodic explicit signal from the bridge terminal over his Representative role informed. The representative terminal can do this role reject. If it assumes the representative role, the bridge terminal informs this Representative terminal over the start time and the duration of his absence (or once over the Periods of attendance and absences).

If, during the absence of the bridge terminal, data is received from a terminal or controller of the first subnetwork whose destination is the bridge terminal or a terminal or controller of the second subnetwork to be reached via the bridge terminal, this data becomes until the bridge terminal returns to the first subnetwork in the cache device 30 the representative terminal. Data whose destination is a station of the agent terminal itself is directly transmitted via the radio switching device 28 to the connection control device 29 which then routes the received data to the desired station.

After the return of the bridge terminal, those in the cache device 30 the representative terminal data in the Einschreibreihenfolge again from the cache device 30 read and sent to the bridge terminal. The representative terminal can either be informed explicitly about the return by a signal from the bridge terminal or implicitly deduce the return time from the period of the presence and absence times of the bridge terminal. Subsequently, during the period of synchronization of the bridge terminal with the first subnetwork, all data whose destination is a terminal or a controller of the second subnetwork or another subnetwork to be reached via the second subnetwork may be removed from the bridge Terminals themselves.

When an example of a possible embodiment two adjacent sub-networks could be one of the sub-networks to work according to the IEEE standard 802.11, while the second to be connected Sub-network according to the ETSI standard HIPERLAN / 2 would operate. This would presuppose that the bridge terminal would be able to post to communicate both standards. A representative terminal must be in in this case only in the first working according to the IEEE 802.11 (CSMA-based) Subnetwork to be set up. In the second HIPERLAN / 2 sub-network could the so-called central controller transmits all transmissions to the bridge terminal while prevent his absence. As a representative terminal in the 802.11 based sub-network should, as previously in general Case mentioned, According to the invention, the central Control station of 802.11 network called "Point Coordinator (PC)" or "Hybric Coordinator" (HC), if active selected become. If in the first sub-network no PC / HC is active, can the bridge terminal Any terminal of this network as a representative terminal choose. For example, could in this case the best receivable neighboring terminal of this network selected as the representative terminal become. The invention is thus suitable according to various standards to connect operating networks.

A other embodiment of the invention could For example, it may be like two or more sub-networks To connect standards. Work two adjacent sub-networks for example, according to the IEEE 802.11 standard on different Frequencies, at least is a bridge terminal as well as a representative terminal in each of the two subnets.

To conclude another possible Design of the representative concept are described, in which at least two or more bridge terminals between the same subnets. When the bridge terminals their So coordinating presence in the neighboring sub-networks that always at least one bridge terminal is present (for example, in Peetz, J .: "HiperLAN2 Multihop Ad Hoc Communication by Multiple-Frequency Forwarding ", Vehicular Technology Conference, Rhodes, May 2001), could each be present Bridge terminal as representative terminal the other bridge terminals established between the same subnetworks act.

Claims (8)

Bridge terminal for connecting multiple subnets ( 1 - 3 ) of a network characterized by comprising means to communicate in at least one of the sub-networks ( 1 - 3 ) select a representative terminal to connect to the bridge terminal ( 4 . 5 ) during periods of time during which the bridge terminal ( 4 . 5 ) in another sub-network ( 1 - 3 ) by receiving and storing data to receive data from the agent terminal when the bridge terminal is again in the subnet ( 1 - 3 ) of the representative terminal works. Bridge terminal according to claim 1, characterized in that the bridge terminal ( 4 ) with a first subnetwork ( 1 ) and a second subnetwork ( 2 ) and that the first sub-network and the second sub-network ( 1 . 2 ) coupling bridge terminal ( 4 ) Means for communicating during a first period with the first subnetwork ( 1 ) and during a second period with the second subnetwork ( 2 ), the bridge terminal ( 4 ) Means for setting up a first representative terminal for the bridge terminal ( 4 ) in the first subnetwork ( 1 ) and to set up a second representative terminal in the second subnetwork ( 1 ). A bridge terminal according to claim 1 or 2, comprising means for informing the agent terminal of its agent role by means of a signal indicating the start time of the communication in the other of the first or second sub-network ( 1 . 2 ) or about the periods of communicating with the first or the second subnetwork. Network with multiple subnets ( 1 - 3 ), whereby a sub-network ( 1 - 3 ) several terminals ( 4 - 16 ) communicating with each other, the subnetworks ( 1 - 3 ) in each case via bridge terminals ( 4 . 5 ) are connected according to one of claims 1 to 3. Network according to claim 4, in which the terminals ( 4 - 16 ) of the subnetworks ( 1 - 3 ) in which a first proxy terminal in a first subnetwork includes means for, during a period in which the bridge terminal is located within a second subnetwork ( 2 ) communicates with the bridge terminal ( 4 ) or from the bridge terminal ( 4 ) to receive further data, further resources ( 30 ) to buffer the data and means for forwarding said data to the bridge terminal ( 4 ), when the bridge terminal returns to the first subnet ( 1 ) communicates; and a second agent terminal includes means for, during a period in which the bridge terminal within the first sub-network ( 1 ) communicates with the bridge terminal ( 4 ) or from the bridge terminal ( 4 ) to receive further data, further resources ( 30 ) to buffer the data and means for forwarding said data to the bridge terminal ( 4 ), when the bridge terminal returns to the second subnet ( 1 ) communicates. Network according to claim 4, characterized in that at least two sub-networks ( 1 - 3 ) operate according to different communication standards and that the bridge terminals ( 4 . 5 ) are intended to exchange data of those sub-networks ( 1 - 3 ), which operate according to different communication standards, to be used and to be able to work according to both communication standards. Network according to claim 4, characterized in that in the presence of several bridge terminals ( 4 . 5 ) between the same subnetworks ( 1 - 3 ) another bridge terminal ( 4 . 5 ) is selected as the representative terminal. Representative terminal within a subnetwork ( 1 - 3 ) of a network, where the network has several subnetworks ( 1 - 3 ), whereby a subnetwork ( 1 - 3 ) several terminals ( 4 - 16 ) that communicate with each other and the subnetworks ( 1 - 3 ) in each case via bridge terminals ( 4 . 5 ), characterized in that the terminals ( 4 - 16 ) communicate decentralized; the agent terminal means around summarizes from a bridge terminal ( 4 . 5 ) of the subnetwork ( 1 - 3 ) as its representative terminal, and further means for receiving and storing it to the bridge terminal ( 4 . 5 ) data of the sub-network during or during periods of time in which the bridge terminal ( 4 . 5 ) operates in a different sub-network, and means for forwarding data to the bridge terminal ( 4 . 5 ), when the bridge terminal ( 4 . 5 ) again in the subnetwork ( 1 - 3 ) of the representative terminal works.